TY - JOUR
T1 - Towards a resolution of the galactic spin crisis
T2 - Mergers, feedback and spin segregation
AU - Maller, Ariyeh H.
AU - Dekel, Avishai
PY - 2002/9/11
Y1 - 2002/9/11
N2 - We model in simple terms the angular momentum problems of galaxy formation in cold dark matter cosmologies, and identify the key elements of a scenario that may solve them. The buildup of angular momentum is modelled via dynamical friction and tidal stripping in a sequence of mergers. We demonstrate how overcooling in incoming haloes leads to a transfer of angular momentum from the baryons to the dark matter, in conflict with observations. By incorporating a simple recipe of supernova feedback, we are able to solve the problems of angular momentum in disc formation. Gas removal from the numerous small incoming haloes which merge to become the low specific angular momentum (low-j) component of the product, eliminates the low-j baryons. Heating and puffing-up of the gas in larger incoming haloes, combined with efficient tidal stripping, reduces the angular momentum loss of baryons due to dynamical friction. Dependence of the feedback effects on the progenitor halo mass implies that the spin of baryons is typically higher for lower-mass haloes. The observed low baryonic fraction in dwarf galaxies is used to calibrate the characteristic velocity associated with supernova feedback, yielding Vfb ∼ 100 km s-1, within the range of theoretical expectations. We then find that the model naturally produces the observed distribution of the spin parameter among dwarf and bright disc galaxies, as well as the j profile inside these galaxies. This suggests that the model indeed captures the main features of a full scenario for resolving the spin crisis.
AB - We model in simple terms the angular momentum problems of galaxy formation in cold dark matter cosmologies, and identify the key elements of a scenario that may solve them. The buildup of angular momentum is modelled via dynamical friction and tidal stripping in a sequence of mergers. We demonstrate how overcooling in incoming haloes leads to a transfer of angular momentum from the baryons to the dark matter, in conflict with observations. By incorporating a simple recipe of supernova feedback, we are able to solve the problems of angular momentum in disc formation. Gas removal from the numerous small incoming haloes which merge to become the low specific angular momentum (low-j) component of the product, eliminates the low-j baryons. Heating and puffing-up of the gas in larger incoming haloes, combined with efficient tidal stripping, reduces the angular momentum loss of baryons due to dynamical friction. Dependence of the feedback effects on the progenitor halo mass implies that the spin of baryons is typically higher for lower-mass haloes. The observed low baryonic fraction in dwarf galaxies is used to calibrate the characteristic velocity associated with supernova feedback, yielding Vfb ∼ 100 km s-1, within the range of theoretical expectations. We then find that the model naturally produces the observed distribution of the spin parameter among dwarf and bright disc galaxies, as well as the j profile inside these galaxies. This suggests that the model indeed captures the main features of a full scenario for resolving the spin crisis.
KW - Cosmology: theory
KW - Dark matter
KW - Galaxies: formation
KW - Galaxies: haloes
KW - Galaxies: spiral
UR - http://www.scopus.com/inward/record.url?scp=0038564249&partnerID=8YFLogxK
U2 - 10.1046/j.1365-8711.2002.05646.x
DO - 10.1046/j.1365-8711.2002.05646.x
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AN - SCOPUS:0038564249
SN - 0035-8711
VL - 335
SP - 487
EP - 498
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -